Amanda Hussey/Sandbox 1
From Proteopedia
One of the CBI Molecules being studied in the University of Massachusetts Amherst Chemistry-Biology Interface Program at UMass Amherst and on display at the Molecular Playground.
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Glutamate Receptor
The AMPA glutamate receptor is a transmembrane protein located primarily at synapses that plays a critical role in communication between neurons. Our lab is interested in the AMPA receptor because strong evidence suggests that changes in location and amount of AMPA receptors at the synapse are central to learning and memory formation. At a molecular level, formation of memory is thought to be governed by changes at synapses between neurons in the brain through a process called long-term potentiation (LTP). One of the key changes involved in potentiation of a synapse is AMPA receptor insertion into the synapse and trafficking of receptors from extrasynaptic areas to the synapse. Studying receptor location and trafficking is one approach to better understanding the underlying changes that are linked to memory formation, and this is one of the primary goals of our lab.
AMPA receptors are iontropic glutamate receptors that allow cations, primarily sodium, to enter into the neuron when the receptor is bound to a ligand such as glutamate. The influx of positive ions depolarizes the membrane, bringing it closer to the threshold necessary for firing an action potential and passing the signal along the neuron to neighboring neurons. Each AMPA receptor is made up of some combination of four subunits, GluA1-4 (or GluR1-4), and in an adult brain most of these receptors consist of GluA1 and GluA2 or GluA2 and GluA3, though other combinations are possible. Receptors containing the GluA2 subunit are calcium impermeable. The molecules on this page are a GluA2 homomer, an AMPA receptor made up of four GluA2 subunits, the GluA1 subunit binding terminal, and GluA3.
Full view of the glutamate receptor shows the overall structure (amino-terminal, ligand-binding and transmembrane domains) in both (MF) and models.
Zooming in at the top of the receptor ()(RCB) one can view the amino terminal domain, which is a part of the extracellular domain. This domain is implicated in receptor assembly, trafficking, and localization.
Moving toward the bottom of the receptor () (SM) one can view the transmembrane domain.
This view () highlights the area where a receptor antagonist, 2K200225, will bind.
Close up view of the ligand binding site ()(AH) of the endogenous ligand glutamate.
S1S2J binding site (AH)
Molecular Playground banner: The glutamate receptor is found in the brain and allows neurons to communicate
3D structures of glutamate receptors
Additional Resources
For additional information, see: Alzheimer's Disease
